DocumentCode
2069398
Title
Numerical computation of eigenenergy and intersubband transition energy of GaAs triangular nanowire embedded in Alx Ga1−x As rectangular wire
Author
Deyasi, Arpan ; Bhattacharyya, Souvik ; Das, Nikhil R.
Author_Institution
Dept. of Electron. & Commun. Eng., RCC Inst. of Inf. Technol., Kolkata, India
fYear
2012
fDate
17-19 Dec. 2012
Firstpage
1
Lastpage
4
Abstract
Energy eigenvalues and intersubband transition energies of a triangular quantum wire have been numerically computed by solving time-independent Schrödinger´s equation with appropriate boundary conditions using finite difference technique for the lowest three eigenstates. Triangular wire is made of GaAs material, which is embedded in a rectangular wire of AlxGa1-xAs. Composition of AlxGa1-xAs is varied to study energy profile and intersubband transition energies of the wire. Dimensional effect is also studied by varying width and height of the triangular wire. The study is carried out taking into consideration conduction band discontinuity and effective mass mismatch at boundaries. Fine optical tuning for quantum wire laser is possible through proper selection of material composition and dimension of the wire.
Keywords
III-V semiconductors; Schrodinger equation; aluminium compounds; finite difference methods; gallium arsenide; nanowires; semiconductor quantum wires; AlGaAs; boundary conditions; conduction band discontinuity; dimensional effect; eigenenergy; energy eigenvalues; energy profile; fine optical tuning; finite difference technique; gallium arsenide triangular nanowire; intersubband transition energy; mass mismatch; material composition; quantum wire laser; rectangular wire; time-independent Schrodinger equation; triangular quantum wire; wire dimension; Energy Eigenvalue; Finite Difference Technique; Intersubband Transition Energies; Triangular Quantum Wire;
fLanguage
English
Publisher
ieee
Conference_Titel
Computers and Devices for Communication (CODEC), 2012 5th International Conference on
Conference_Location
Kolkata
Print_ISBN
978-1-4673-2619-3
Type
conf
DOI
10.1109/CODEC.2012.6509258
Filename
6509258
Link To Document